Coagulation reaction tank

ABSTRACT

A coagulation reaction tank comprises a cylindrical tank provided in the central part thereof with a rotary stirring mechanism furnished with stirring vanes and a filtration tank for introducing the liquid from within the cylindrical tank in the form of filtrate and discharging the filtrate out of the cylindrical tank. This coagulation reaction tank is characterized by the fact that the filtration tank provided in the bottom thereof with slits is disposed in the cylindrical tank above the stirring vanes or the cylindrical tank provided in the upper part of the wall thereof with slits and the filtration tank is disposed outside the slits.

DESCRIPTION

1. Technical Field

This invention relates to a coagulation reaction tank which, by stirringsludge supplied thereto in combination with a coagulant by the use ofrotary stirring means provided with stirring vanes, produces flocpossessing ample strength even when the sludge is supplied in a lowconcentration.

2. Background Art

As a coagulation reaction tank of this class, Japanese Utility ModelPublic Disclosure SHO 62(1987)-48405 discloses one comprising acylindrical tank, rotary stirring means disposed upright in the centralpart of the cylindrical tank, provided with stirring vanes, and adaptedto stir sludge supplied thereto with a coagulant and convert the sludgeinto floc, and a filtration tank disposed concentrically in the upperinternal part of above the cylindrical tank and adapted to draw inthrough the bottom thereof the liquid from within the cylindrical tankin the form of filtrate and discharge the filtrate out of thecylindrical tank (first conventional technique). Japanese Utility ModelPublic Disclosure SHO 62(1987)-118602 discloses a coagulation reactiontank which comprises a cylindrical tank and a filtration tank disposedconcentrically in the upper internal part of the cylindrical tank andadapted to draw in the liquid from within the cylindrical tank in theform of filtrate through slits formed in a plurality of horizontalstages in the outer peripheral wall of the filtration tank and dischargethe filtrate out of the cylindrical tank (second conventionaltechnique).

Further, a coagulation reaction tank using a cylindrical tank andcausing the liquid within the tank to be taken out in the form offiltrate from the upper part of the tank wall is disclosed in JapaneseUtility Model Public Disclosure SHO 61(1986)-810 and SHO 61(1986)-811(third conventional technique).

The conventional techniques are invariably capable of dischargingfiltrate containing substantially no floc from within a filtration tankand releasing floc of ample strength from a cylindrical tank. In thecase of the first conventional technique, since the bottom of thefiltration tank is formed with a punched plate or a netting, minuteparticles of the floc or minute fibrous particles entrained by thesludge clog the holes in the punched plate or the meshes of the netting.

As a solution, therefore, the rotary vanes of the stirring means areprovided with a wiper such as brushes or rubber plates adapted to berotated and rubbed against the upper and lower surfaces of the bottom ofthe filtration tank so as to sweep the bottom of the filtration tank.The wiper, however, fails to manifest a fully satisfactory cleaningeffect because the fibrous particles entangle on the brushes or rubberplates. In the case of the second conventional technique, the minuteparticles of floc or the minute fibrous particles entrained by thesludge clog the multiplicity of horizontal slits in the outer peripheralwall of the filtration tank.

As a solution, the rotary shaft of the stirring means is provided withbrushes attached radially thereto and adapted to rub the inner surfaceof the aforementioned outer peripheral wall and prevent the slits fromthe clogging. The brushes, however, fail to manifest fully satisfactorycleaning effect because the fibrous particles entangle on the brushes.

In the case of the third conventional technique, since vertical slitsare formed in the tank wall, the fibrous particles in the sludge catchin the slits. As a solution, a rotating brush is brought into contactwith the slits from outside the tank to clean the slits. The rotarybrush, however, fails to manifest a fully satisfactory cleaning effectbecause the fibrous particles similarly entangle on the brush.

DISCLOSURE OF THE INVENTION

The present invention is characterized by the fact that theaforementioned filtration tank is disposed inside the cylindrical tankin such a manner that the bottom thereof falls above the region ofrotation of the stirring vanes, the slits for drawing in the liquid fromwithin the cylindrical tank in the form of filtrate are formed in thebottom of the filtration tank in arcuate shapes concentrical with thecylindrical tank, and the upper edges of the stirring vanes arejuxtaposed to the lower surface of the bottom of the filtration tank.

The present invention is further characterized by the fact that thefiltration tank is disposed outside the upper outer periphery of thewall of the cylindrical tank, the slits for introducing the liquid fromwithin the cylindrical tank in the form of filtrate into the filtrationtank are formed horizontally in the upper part of the wall of thecylindrical tank enclosed with the filtration tank, and the outer edgesof the stirring vanes are juxtaposed to the upper inner surface of thewall of the cylindrical tank.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view illustrating a typical coagulation reactiontank as one embodiment of the first aspect of this invention, with partof a cylindrical tank cut away. FIG. 2 is a plan view of FIG. 1. FIG. 3is a perspective view illustrating a typical coagulation reaction tankas a further embodiment of this invention, with part of a cylindricaltank cut away. FIG. 4 is a magnified side view of the essential part.

BEST MODE FOR CARRYING OUT THE INVENTION

Now, the present invention will be described with reference to thedrawings.

In each of the illustrated embodiments, 1 stands for a cylindrical tank,2 rotary agitating means disposed upright in the central part of thetank 1 mentioned above and driven rotationally by a motor and atransmission, 3 and 4 for a sludge feed pipe and a chemical feed pipefor supplying sludge and a coagulant to the bottom part of the tank, and5 for a sludge discharge pipe for discharging coagulated floc.

To a rotary shaft 2' of the rotary stirring means, stirring vanes 6a, 6bare attached in two vertical levels radially at angular intervals of180°.

FIG. 1 and FIG. 2 represent one embodiment of the present invention.Along the inner wall of the cylindrical tank 1, a filtration tank 7 isdisposed which has a cross section slightly smaller than a semicircleand a curvature identical with that of the inner wall of the cylindricaltank 1. The upper end of the filtration tank 7 is flush with the upperend of the cylindrical tank 1 and the bottom 7' of the filtration tank 7is so near to the upper edges of the stirring vanes 6a in the upperlevel as to be separated only by a distance of about 5 to 20 mmtherefrom. In the bottom 7', a multiplicity of arcuate slits 8 aredisposed in circularly parallel rows concentrically with the cylindricaltank 1. These slits 8 have a width of not more than 5 mm, preferably inthe range of about 1 to 2 mm as radially separated by intervals of about5 mm. The slits are circumferentially separated by intervals of about 2mm. In the present embodiment, a discharge pipe 9 is laid through thewall of the cylindrical tank 1 so as to release the filtrate from thefiltration tank 7.

The sludge and the coagulant supplied respectively through the sludgefeed pipe 3 and the chemical feed pipe 4 to the central part of thebottom of the cylindrical tank, during their retention within the tank,are homogeneously mixed and allowed to react with each other by thestirring action of the stirring vanes 6a, 6b of the rotary stirringmeans 2. The water which enters the interior of the filtration tank 7through the slits in the bottom is discharged as by a pump out of thetank through a discharge pipe 9. As a result, the sludge continuouslysupplied is amply concentrated and discharged in the form of floc ofhigh strength through the sludge discharge pipe 5 and thence forwardedto, for example, a dehydrator.

The stirring vanes 6a in the upper level are rotated to generate ahorizontal rotational current immediately below the bottom 7' of thefiltration tank 7. Since the slits 8 formed in the bottom of thefiltration tank have arcuate shapes concentrical with the rotationalcurrent and the minute particles of floc and the minute fibrousparticles flow in the same direction as the slits under the bottom 7',the particles in motion are not entangled in the slits and, at the sametime, the floc continues to roll under the bottom and consequently gaingradually in density and strength.

The stirring vanes 6a in the upper level are flat plates having auniform vertical width throughout the entire length from the basal partfixed to the rotary shaft 2' to the leading end as illustrated in thediagram. The stirring vanes 6b in the lower level are desired to beformed each in the shape of a paddle consisting of a basal part 10attached to the rotary shaft 2' and having roughly one half of theentire length and a smaller vertical width and a free end part 11 havingthe remainder of length and a larger vertical width. The reason for thisconstruction is that the paddle-shaped stirring vanes push the wateroutwardly with their free end parts 11 of large width under thehorizontally rotational current a generated by the stirring vanes in theupper level, the current of the outwardly pushed water is rotated and isdivided near the inner wall of the cylindrical tank into an ascendingcurrent b and a descending current b', the ascending current b comesinto contact with the horizontally circulated current generated by theflat-plate stirring vanes in the upper level and consequently decends inthe direction of the central part, the descending current b' ascends inthe central part along the bottom surface and, as the result, upper andlower rotationally circulated currents are generated in the central partand the bottom part of the cylindrical tank, and the sludge and thecoagulant supplied to the central part of the bottom of the tank areallowed to ride on the currents b, b' and efficiently brought intomixing contact with the floc already formed and enhance the coagulation.When the free end parts 11 of a larger width are bent backwardlyrelative to the direction of rotation of the vanes as illustrated in thediagram (as with an angle of 45°), the force with which the free endparts push the water toward the inner wall of the tank is increased and,as the result, the rotational circulating current acquires greaterstrength and the efficiency of mixing and contact is enhanced. Whenguide plates 12 and 13 which are either straight or curved asillustrated and extended in the direction of rotation of the stirringvanes and gradually separated from the inner wall toward the leadingends thereof are disposed in the lower end part of the inner wall of thecylindrical tank and in the intermediate part between the stirring vanes6a in the upper level and the stirring vanes in the lower level, theupper circulating current b which flows along the underside of thehorizontally circulating current and then descends in the central partand the lower circulating current b' which flows along the tank bottomand then ascends in the central part are accelerated similarly toenhance the efficiency of mixing and contact.

In a circular tank constructed as illustrated in FIG. 1 and FIG. 2 andhaving an available inner volume of 100 liters (about 50 cm in diameterand about 70 cm in height), sludge (pH 5.1, TS (%) 1.42, VTS (%/TS)64.4, SS (%) 1.21, VSS (%/SS) 65.44, fiber content 10.3, T-P (mg/liter)228.0, supernatant PO₄ -P (mg/liter) 44.2) was continuously supplied incombination with a coagulant and subjected to coagulation andconcentration. Consequently, a dense and strong floc of particles 10 to20 mm in diameter was obtained through the sludge discharge pipe 5.

In the operation of the cylindrical tank, the revolution number of therotary shaft was 40 rpm, the length of the flat-plate stirring vanes 6ain the upper level was 20 cm and the vertical width thereof was 8 cm,the length of the basal part 10 of the paddle-shaped stirring vanes 6bin the lower level was 10 cm and the vertical width thereof was 4 cm,the length of the free end part 11 was 10 cm and the vertical widththereof was 12 cm, the peripheral speed of the leading end of thestirring vanes in both levels was 50 m/minute, the retention time of thesludge was 10 minutes, the horizontal cross-sectional area of thefiltration tank was 25.6% of the horizontal cross-sectional area of thetank, the surface area of the opening in the arcuate slits in the bottomof the filtration tank was 28.6% of the horizontal cross-sectional areaof the filtration tank, the depth of immersion of the filtration tankwas 5 cm below the water level, the distance between the flat-platestirring vanes in the upper level and the bottom of the filtration tankwas 1 cm, and the width of the arcuate slits was 2 mm. During theoperation, the arcuate slits in the bottom of the filtration tank werenot at all clogged and were not entangled by fibrous particles.

The filtration tank 7 may be installed as a stationary device inside thecylindrical tank 1 and the filtered water entering the filtration tankthrough the arcuate slits 8 in the bottom may be discharged with a pumpthrough the discharge pipe 9 laid through the wall of the cylindricaltank. The filtration tank 7 may otherwise be made of stainless steelseparately of the cylindrical tank 1 and it may be suspended inside thecylindrical tank with the aid of suspending metal pieces 14 joined tothe arcuate part thereof and suspended from the edge of the cylindricaltank. In this case, the liquid which enters the filtration tank may bedischarged by a siphon.

FIG. 3 and FIG. 4 represent a coagulation reaction tank as a furtherembodiment of the present invention. The present coagulation reactiontank differs from that of the embodiment of FIG. 1 and FIG. 2 in respectthat the filtration tank 7 is disposed outside the upper outer peripheryof the cylindrical tank 1 and horizontal slits 15 are disposed in aplurality of vertical stages in the upper part of the wall of thecylindrical tank 1 enclosed with the filtration tank 7, preferably inthe region of rotation of the stirring vanes 6a in the upper level.Owing to this construction, the upper edge of the stirring vanes 6a inthe upper level falls directly below the water level in the cylindricaltank 1.

In the present embodiment, the filtration tank 7 is laid throughoutsubstantially one half of the circumference of the cylindrical tankoutside the upper outer periphery of the wall of the cylindrical tank.Of course, it may be laid throughout the entire circumference of thecylindrical tank so as to enclose the cylindrical tank therewith.

The outer edges or the free edges of the stirring vanes 6a areapproximated so much to the inner surface of the wall of the cylindricaltank containing the slits 15 as to be separated therefrom by a distanceof about 5 to 20 mm. The outer edges may be covered with a rubber plate,when necessary, so that the rubber plates will rub the inner surface ofthe wall of the cylindrical tank while the stirring vanes are inrotation.

The vertical width of the slits 15 is not more than 5 mm and preferablyin the range of 1 to 2 mm. The vertical distance between the slits inthe upper stage and those in the lower stage is about 5 mm.

In the present embodiment, too, the sludge and the coagulant supplied tothe central part of the bottom inside the cylindrical tank through thesludge feed pipe 3 and the chemical feed pipe 4, during their retentioninside the tank, are homogeneously mixed and caused to react with eachother by the stirring action of the stirring vanes 6a, 6b of the rotarystirring means. The water which enters the interior of the filtrationtank 7 through the slits 15 in the tank wall is discharged out of thetank through the discharge pipe 9 by means of a pump. Consequently, thesludge continuously supplied is thoroughly concentrated to give rise tofloc of high strength. This floc is discharged through the sludgedischarge pipe 5 and then forwarded to, for example, a dehydratingdevice.

The stirring vanes 6a in the upper level are horizontally rotatedclosely to the upper inner surface of the wall of the cylindrical tankcontaining the slits 15. The floc produced inside the cylindrical tankis pushed by the stirring vanes 6a and caused to roll on the innersurface of the wall along the slits 15. Thus, the floc is incapable ofclogging the slits. Moreover, the floc gradually gains in density andstrength by being rolled on the inner surface of the wall along theslits.

Instead of causing the water which flows into the filtration tank 7through the slits 15 to be discharged through the discharge pipe 9 bymeans of a pump, the water may be discharged by controlling the flowvolume of the water by V notches formed in the trough attached to theexterior of the filtration tank. The level in which the sludge dischargepipe 5 is laid relative to the cylindrical tank 1 may fall where theslits 15 are located in the cylindrical tank. Otherwise, this level maybe below the region of rotation of the stirring vanes in the upper levelas illustrated in FIG. 4.

In either of the embodiments, the sludge and the coagulant have beendescribed as being supplied separately of each other to the central partof the bottom of the tank interior. Optionally, the sludge may be mixedwith the coagulant prior to supply to the tank and then supplied in thestate mixed with coagulant to the central part of the bottom of the tankinterior.

Industrial Applicability

The present invention, by forming the slits 8, 15 for passage of waterfrom the cylindrical tank to the filtration tank in a directioncoinciding with the direction in which the current of water generatedwithin the cylindrical tank by the stirring vanes and enabling theformed floc to be driven forward with the stirring vanes near the slits,enables the coagulation reaction tank to be operated safely withoutrequiring use of brushes or scrapers, effects coagulation andconcentration of the sludge without entailing the problem of clogging,and produces dense and strong floc. Particularly when the coagulationreaction tank is used for dephosphorized biosludge, it is capable ofsequestering phosphorus and treating the sludge without sufferingrelease of phosphorus on the liquid side.

We claim:
 1. A coagulation reaction tank comprising:a cylindrical tank;rotary stirring means positioned in a central part of said cylindricaltank and comprising stirring vanes for stirring sludge and a coagulantlocated within the tank interior and converting the sludge into floc;and a filtration tank mounted on said cylindrical tank for admittingliquid from within said tank in the form of filtrate and dischargingsaid filtrate out of said cylindrical tank; wherein said filtration tankis mounted inside said cylindrical tank such that the bottom of saidfiltration tank falls above a region of rotation of said stirring vanes,the bottom of said filtration tank comprises slits formed in an arcuateshape concentrically with said cylindrical tank for introducing theliquid from within said cylindrical tank in the form of filtrate, and adistance between the upper edges of said stirring vanes and the lowersurface of the bottom of said filtration tank is about 5 to 20 mm.